U.S. patent application number 14/520855 was filed with the patent office on 2015-02-05 for biological information detector and biological information measuring device.
The applicant listed for this patent is SEIKO EPSON CORPORATION. Invention is credited to Yoshitaka IIJIMA, Shigemi SATO, Hideto YAMASHITA.
Application Number | 20150038807 14/520855 |
Document ID | / |
Family ID | 44225097 |
Filed Date | 2015-02-05 |
United States Patent
Application |
20150038807 |
Kind Code |
A1 |
YAMASHITA; Hideto ; et
al. |
February 5, 2015 |
BIOLOGICAL INFORMATION DETECTOR AND BIOLOGICAL INFORMATION
MEASURING DEVICE
Abstract
A biological information detector is adapted to be attached to a
user's body. The biological information detector includes a
light-emitting part, a reflecting part, a light-receiving part, a
processing unit and a support part. The light-emitting part is
configured to emit light toward the user's body. The reflecting
part is configured to be disposed in periphery of the
light-emitting part and to reflect at least part of the light
emitted by the light-emitting part toward the user's body. The
light-receiving part is configured to receive light reflected at
the user's body to produce a light reception signal. The processing
unit is configured to process the light reception signal to produce
biological information. The support part supports the
light-emitting part. A thickness of the support part is within a
range from 50 .mu.m to 1000 .mu.m.
Inventors: |
YAMASHITA; Hideto; (Suwa,
JP) ; IIJIMA; Yoshitaka; (Shiojiri, JP) ;
SATO; Shigemi; (Asahi-mura, JP) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
SEIKO EPSON CORPORATION |
Tokyo |
|
JP |
|
|
Family ID: |
44225097 |
Appl. No.: |
14/520855 |
Filed: |
October 22, 2014 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
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14275290 |
May 12, 2014 |
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14520855 |
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|
12973259 |
Dec 20, 2010 |
8758239 |
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14275290 |
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Current U.S.
Class: |
600/301 ;
600/476 |
Current CPC
Class: |
A61B 5/021 20130101;
A61B 5/02055 20130101; A61B 5/0261 20130101; A61B 5/1118 20130101;
A61B 5/14552 20130101; A61B 5/11 20130101; A61B 5/02427 20130101;
A61B 5/6824 20130101; A61B 5/0059 20130101; A61B 5/02438 20130101;
A61B 5/01 20130101; A61B 5/681 20130101; A61B 5/7278 20130101 |
Class at
Publication: |
600/301 ;
600/476 |
International
Class: |
A61B 5/1455 20060101
A61B005/1455; A61B 5/00 20060101 A61B005/00; A61B 5/11 20060101
A61B005/11; A61B 5/0205 20060101 A61B005/0205 |
Foreign Application Data
Date |
Code |
Application Number |
Jan 5, 2010 |
JP |
2010-000453 |
Claims
1. A biological information detector adapted to be attached to a
user's body, the biological information detector comprising: a
light-emitting part configured to emit light toward the user's
body; a reflecting part configured to be disposed in periphery of
the light-emitting part and to reflect at least part of the light
emitted by the light-emitting part toward the user's body; a
light-receiving part configured to receive light reflected at the
user's body to produce a light reception signal; a processing unit
configured to process the light reception signal to produce
biological information; and a support part supporting the
light-emitting part, a thickness of the support part being within a
range from 50 .mu.m to 1000 .mu.m.
2. The biological information detector according to claim 1,
wherein the reflecting part includes a reflecting surface parallel
to a light-emitting surface facing the user's body, the reflecting
part having a high reflectivity region.
3. The biological information detector according to claim 2,
wherein the reflecting surface has a reflectivity of 80% to
90%.
4. The biological information detector according to claim 1,
wherein the reflecting part includes a quadrilateral-shaped
region.
5. The biological information detector according to claim 4,
wherein a length of at least one side of the quadrilateral-shaped
region is 100 .mu.m to 10,000 .mu.m.
6. The biological information detector according to claim 2,
wherein the reflecting surface has a curve-shaped corner.
7. The biological information detector according to claim 2,
wherein the reflecting surface has a right angle shaped corner.
8. The biological information detector according to claim 2,
wherein the reflecting surface has the high reflectivity region and
a low reflectivity region, and the high reflectivity region does
not overlap the light-emitting part in plan view.
9. The biological information detector according to claim 1,
further comprising a protecting part configured to protect the
reflecting part and the light-emitting part, the protecting part
being made of a transparent material configured to transmit the
light reflected at a detection site of the user's body.
10. The biological information detector according to claim 9,
wherein a thickness of the protecting part is within a range from 1
.mu.m to 1000 .mu.m.
11. The biological information detector according to claim 1,
further comprising a substrate physically in contact with the
light-receiving part and the reflecting part, a thickness of the
substrate being within a range from 10 .mu.m to 1000 .mu.m.
12. The biological information detector according to claim 11,
further comprising a wiring for at least one of the light-emitting
part and the light-receiving part, the wiring being disposed on the
substrate.
13. The biological information detector according to claim 1,
further comprising an acceleration detecting part configured to
detect a movement of the user's body and to generate an
acceleration signal.
14. The biological information detector according to claim 13,
further comprising: a first A/D conversion circuit configured to
perform A/D conversion of the light reception signal from the
light-receiving part for the processing unit; and a second A/D
conversion circuit configured to perform A/D conversion of the
acceleration signal from the acceleration detecting part for the
processing unit, wherein the processing unit is configured to
produce the biological information using signals from the first A/D
conversion circuit and the second A/D conversion circuit.
15. The biological information detector according to claim 1,
wherein the light-emitting part is configured to emit the light
having a maximum intensity within a wavelength range of 425 nm to
625 nm.
16. The biological information detector according to claim 1,
wherein the light-emitting part is configured to emit green
light.
17. The biological information detector according to claim 1,
wherein a thickness of at least one of the light-emitting part and
the light-receiving part is within a range from 20 .mu.m to 1000
.mu.m.
18. The biological information detector according to claim 1,
wherein the light-emitting part is configured to emit light toward
the user's body in an intermittent manner in order to reduce power
consumption.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation application of U.S.
application Ser. No. 14/275,290 filed on May 12, 2014, which is a
continuation application of U.S. application Ser. No. 12/973,259
filed on Dec. 20, 2010, now U.S. Pat. No. 8,758,239. This
application claims priority to Japanese Application No. 2010-000453
filed on Jan. 5, 2010. The entire disclosures of U.S. application
Ser. Nos. 14/275,290 and 12/973,259 and Japanese Application No.
2010-000453 are hereby incorporated herein by reference.
BACKGROUND
[0002] 1. Technological Field
[0003] The present invention relates to a biological information
detector and a biological information measuring device and similar
devices.
[0004] 2. Background Technology
[0005] A biological information measuring device measures human
biological information such as, for example, pulse rate, blood
oxygen saturation level, body temperature, or heart rate, and an
example of a biological information measuring device is a pulse
rate monitor for measuring the pulse rate. Also, a biological
information measuring device such as a pulse rate monitor may be
installed in a clock, a mobile phone, a pager, a PC, or another
electrical device, or may be combined with the electrical device.
The biological information measuring device has a biological
information detector for detecting biological information, and the
biological information detector includes a light-emitting part for
emitting light towards a detection site of a test subject (e.g. a
user), and a light-receiving part for receiving light having
biological information from the detection site.
[0006] In Japanese Laid-Open Patent Application Publication No.
2004-337605 (hereinafter "Patent Citation 1"), there is disclosed a
pulse rate monitor (or in a broader sense, a biological information
measuring device). A light-receiving part (e.g. a light-receiving
part 12 in FIG. 16 of Patent Citation 1) of the pulse rate monitor
receives light reflected at a detection site (e.g. dotted line in
FIG. 16 of Patent Citation 1) via a diffusion reflection plane
(e.g. reflecting part 131 in FIG. 16 of Patent Citation 1). In an
optical probe 1 in Patent Citation 1 (or in a broader sense, a
biological information detector), a light-emitting part 11 and the
light-receiving part 12 overlap in plan view, and the size of the
optical probe is reduced.
SUMMARY
[0007] In the optical probe 1 of Patent Citation 1, in an instance
in which there is a significant level of noise arising from to e.g.
external light, or under similar circumstances, the detection
accuracy of the biological information detector is poor.
[0008] According to several modes of the present invention, it is
possible to provide a biological information detector and a
biological information measuring device in which the detection
accuracy or the measurement accuracy can be improved.
[0009] A biological information detector according to one aspect is
adapted to be attached to a user's body. The biological information
detector includes a light-emitting part, a reflecting part, a
light-receiving part, a processing unit and a support part. The
light-emitting part is configured to emit light toward the user's
body. The reflecting part is configured to be disposed in periphery
of the light-emitting part and to reflect at least part of the
light emitted by the light-emitting part toward the user's body.
The light-receiving part is configured to receive light reflected
at the user's body to produce a light reception signal. The
processing unit is configured to process the light reception signal
to produce biological information. The support part supports the
light-emitting part. A thickness of the support part is within a
range from 50 .mu.m to 1000 .mu.m.
BRIEF DESCRIPTION OF THE DRAWINGS
[0010] FIG. 1 is an example of a configuration of a biological
information detector according to a present embodiment;
[0011] FIG. 2 includes diagrams (A), (B), and (C) that are examples
of configurations of a first reflecting part;
[0012] FIG. 3 includes diagrams (A) and (B) that are examples of
the outer appearance of the first reflecting part and a
light-emitting part;
[0013] FIG. 4 is another example of a configuration of the
biological information detector according to the present
embodiment;
[0014] FIG. 5 is an example of an outer appearance of a
light-receiving part;
[0015] FIG. 6 is a schematic diagram showing a setting position of
the second reflecting part;
[0016] FIG. 7 is a diagram showing a relationship between the
setting position of the second reflecting part and the amount of
light received at the light-receiving part;
[0017] FIG. 8 includes diagrams (A) and (B) that are examples of
the outer appearance of a biological information measuring device
containing the biological information detector; and
[0018] FIG. 9 is an example of a configuration of the biological
information measuring device.
DESCRIPTION OF EXEMPLARY EMBODIMENTS
[0019] A description shall now be given for the present embodiment.
The present embodiment described below is not intended to unduly
limit the scope of the Claims of the present embodiment. Not every
configuration described in the present embodiment is necessarily an
indispensible constituent feature of the present invention.
1. Biological Information Detector
[0020] FIG. 1 shows an example of a configuration of a biological
information detector according to the present embodiment. As shown
in FIG. 1, the biological information detector contains a
light-emitting part 14, a first reflecting part 12, a
light-receiving part 16, and a second reflecting part 18. The
light-emitting part 14 generates a first light R1 directed at a
detection site O of a test subject (e.g. a user), and a second
light R2 directed at a direction other than a direction of the
detection site O (i.e., directed at the first reflecting part 12).
The first reflecting part 12 reflects the second light R2 and
directs the second light R2 towards the detection site O. The
light-receiving part 16 receives lights R1', R2' (i.e., reflected
lights), having biological information, the lights R1', R2'
produced by each of the first light R1 and the second light R2
being reflected at the detection site O. The second reflecting part
18 reflects the lights R1', R2' having biological information from
the detection site O (i.e. the reflected lights) and directs the
lights R1', R2' towards the light-receiving part 16. The presence
of the first reflecting part 12 causes the light second light R2,
that does not directly reach the detection site O of the test
subject (i.e., the user), to reach the detection site O. In other
words, the amount of light reaching the detection site O via the
first reflecting part 12 increases, and the efficiency of the
light-emitting part 14 increases. Therefore, the detection accuracy
(i.e., the signal-to-noise ratio) of the biological information
detector increases.
[0021] In Patent Citation 1, there is disclosed a configuration
corresponding to the second reflecting part 18 (i.e., a reflecting
part 131 in FIG. 16 of Patent Citation 1). Specifically, the
light-receiving part 12 in FIG. 16 of Patent Citation 1 receives
light reflected at a detection site via the reflecting part 131.
However, in Patent Citation 1, a configuration corresponding to the
first reflecting part 12 is not disclosed. In other words, at the
time of filing, those skilled in the art had not been aware of the
issue of increasing the efficiency of the light-emitting part 11 in
FIG. 16 in Patent Citation 1.
[0022] In the example shown in FIG. 1, the detection site O (e.g. a
blood vessel) is within the test subject. As shown in FIG. 1, the
light-emitting part 14 may have a first light-emitting surface 14A
for emitting the first light R1, the first light-emitting surface
14A facing the detection site O. The first light R1 travels into
the test subject and diffuses or scatters at the epidermis, the
dermis, and the subcutaneous tissue. The first light R1 then
reaches the detection site O, and is reflected at the detection
site O. The reflected light R1' reflected at the detection site O
diffuses or scatters at the subcutaneous tissue, the dermis, and
the epidermis, and travels to the second reflecting part 18. The
first light R1 is also partially absorbed at the blood vessel (or
in a broader sense, the detection site O). Therefore, due to an
effect of a pulse, the rate of absorption at the blood vessel
varies, and the amount of the reflected light R1' reflected at the
detection site O also varies. Biological information (e.g. pulse
rate) is thus reflected in the reflected light R1' reflected at the
detection site O.
[0023] In the example shown in FIG. 1, the light-emitting part 14
may also have a second light-emitting surface 14B for emitting the
second light R2, the second light-emitting surface 14B being a side
surface of the first light-emitting surface 14A. In such an
instance, the first reflecting part 12 may have a wall part
surrounding the second light-emitting surface 14B, and the wall
part may have a first reflecting surface (corresponding to label
12-2 shown in FIGS. 2(A) through 2(C)) capable of reflecting the
second light R2 towards the detection site O. The second light R2
is not necessarily limited to that emitted from the second
light-emitting surface 14B. Specifically, the first reflecting
surface (label 12-2 shown in FIGS. 2(A) through 2(C)) reflects
light other than light travelling directly from the light-emitting
part 14 to the detection site O (i.e., the second light R2) and
directs the second light R2 towards the detection site O.
[0024] The second light R2 also travels into the test subject, and
the reflected light R2' reflected at the detection site O travels
towards the second reflecting part 18. Biological information
(i.e., the pulse rate) is also reflected in the reflected light R2'
reflected at the detection site O. In the example shown in FIG. 1,
the first light R1 is partially reflected at a surface SA of the
test subject (e.g. a skin surface). In an instance in which the
detection site O is within the test subject, biological information
(i.e., the pulse rate) is not reflected in reflected light R1''
reflected at the surface SA of the test subject (i.e., a directly
reflected light).
[0025] The wall part of the first reflecting part 12 may further
have a second reflecting surface (corresponding to 12-3 in FIGS.
2(A) and 2(C)) for reflecting light not having biological
information (i.e., invalid light; noise) reflected at the surface
of the test subject, thereby minimizing incidence of light not
having biological information onto the light-receiving part.
[0026] Examples of configurations of the biological information
detector are not limited by that shown in FIG. 1, and the shape, or
a similar attribute, of a part of the example of configuration
(e.g. the first reflecting part 12) may be modified. The biological
information may also be blood oxygen saturation level, body
temperature, heart rate, or a similar variable; and the detection
site O may be positioned at the surface SA of the test subject. In
the example shown in FIG. 1, each of the first light R1 and the
second light R2 is shown by a single line; however, in reality, the
light-emitting part 14 emits many light beams in a variety of
directions.
[0027] The light-emitting part 14 is, for example, an LED. The
light emitted by the LED has a maximum intensity (or in a broader
sense, a peak intensity) within a wavelength range of e.g. 425 nm
to 625 nm, and is e.g. green in color. The thickness of the
light-emitting part 14 is e.g. 20 .mu.m to 1000 .mu.m. The
light-receiving part 16 is e.g. a photodiode, and can generally be
formed by a silicon photodiode. The thickness of the
light-receiving part 16 is e.g. 20 .mu.m to 1000 .mu.m. The silicon
photodiode has a maximum sensitivity (or in a broader sense, a peak
sensitivity) for received light having a wavelength within a range
of e.g. 800 nm to 1000 nm. Ideally, the light-receiving part 16 is
formed by a gallium arsenide phosphide photodiode, and the gallium
arsenide phosphide photodiode has a maximum sensitivity (or in a
broader sense, a peak sensitivity) for received light having a
wavelength within a range of e.g. 550 nm to 650 nm. Since
biological substances (water or hemoglobin) readily allow
transmission of infrared light within a wavelength range of 700 nm
to 1100 nm, the light-receiving part 16 formed by the gallium
arsenide phosphide photodiode is more capable of reducing noise
components arising from external light than the light-receiving
part 16 formed by the silicon photodiode.
[0028] FIGS. 2(A), 2(B), and 2(C) respectively show an example of a
configuration of the first reflecting part 12 shown in FIG. 1. As
shown in FIG. 2(A), the first reflecting part 12 may have a support
part 12-1 for supporting the light-emitting part 14, and an inner
wall surface 12-2 and a top surface 12-3 of the wall part
surrounding the second light-emitting surface 14B of the
light-emitting part 14. In FIGS. 2(A) through 2(C), the
light-emitting part 14 is omitted. In the example shown in FIG.
2(A), the first reflecting part 12 is capable of reflecting the
second light R2 towards the detection site O off the inner wall
surface 12-2 (see FIG. 1), and has the first reflecting surface on
the inner wall surface 12-2. The thickness of the support part 12-1
is e.g. 50 .mu.m to 1000 .mu.m, and the thickness of the top
surface 12-3 is e.g. 100 .mu.m to 1000 .mu.m. The first reflecting
part 12 may not necessarily have the support part 12-1, and the
light-emitting part 14 may be supported by a part other than the
first reflecting part 12.
[0029] In the example shown in FIG. 2(A), the inner wall surface
12-2 has an inclined surface (12-2) which, with increasing distance
in a width direction (i.e., a first direction) from a center of the
first reflecting part 12, inclines towards the detection site O in
a height direction (i.e., a direction that is orthogonal with the
first direction), in cross-section view. The inclined surface
(12-2) in FIG. 2(A) is formed by, in cross-section view, an
inclined plane, but may also be a curved surface shown in e.g. FIG.
2(C), or a similar inclined surface. The inner wall surface 12-2
may also be formed as a plurality of inclined flat surfaces whose
angle of inclination vary from one another, or by a curved surface
having a plurality of curvatures. In an instance in which the inner
wall surface 12-2 of the first reflecting part 12 has an inclined
surface, the inner wall surface 12-2 of the first reflecting part
12 is capable of reflecting the second light R2 towards the
detection site O. In other words, the inclined surface on the inner
wall surface 12-2 of the first reflecting part 12 can be said to be
the first reflecting surface for improving the directivity of the
light-emitting part 14. In such an instance, the amount of light
reaching the detection site O increases further. The top surface
12-3 shown in FIGS. 2(A) and 2(C) may be omitted as shown, for
example, in FIG. 2(B). In an instance in which the first reflecting
part 12 has the top surface 12-3, the reflected light R1''
reflected at the surface SA of the test subject (i.e., the directly
reflected light) can be reflected towards the detection site O or
surroundings thereof, and the reflected light R1'' is deterred from
reaching the light-receiving part 16 (see FIG. 1). Specifically,
the top surface 12-3 shown in FIGS. 2(A) and 2(C) can be said to be
the second reflecting surface for reflecting the directly reflected
light (or in a broader sense, noise) that would otherwise reach the
second reflecting part 18 and the light-receiving part 16, and
reducing noise. In FIGS. 2(A) through 2(C), a range indicated by
label 12-4 function as a mirror surface part.
[0030] In the example shown in FIG. 1, the first reflecting part 12
may project towards the detection site O by e.g. a predetermined
height .DELTA.h1 (where .DELTA.h1 is e.g. 50 .mu.m to 950 .mu.m) in
relation to a surface of the light-emitting part 14 that determines
the shortest distance relative to the surface SA of the test
subject (e.g. the first light-emitting surface 14A). In other
words, a spacing between the first reflecting part 12 and the
surface SA of the test subject (e.g. .DELTA.h2=.DELTA.h0-.DELTA.h1,
where .DELTA.h2 is 200 .mu.m to 1200 .mu.m) may be smaller than a
spacing that represents the shortest distance between the
light-receiving part 14 and the surface SA of the test subject
(e.g. .DELTA.h0=.DELTA.h1+.DELTA.h2). Therefore, in the first
reflecting part 12, the presence of e.g. a projection .DELTA.h1
from the light-emitting part 14 makes it possible to increase the
area of the first reflecting surface (12-2) and increase the amount
of light reaching the detection site O. Also, with regards to the
light reflected at the detection site O, the presence of a space
.DELTA.h2 between the first reflecting part 12 and the surface SA
of the test subject makes it possible to obtain a light path for
the light to reach the second reflecting part 18 from the detection
site O. Also, in an instance in which the first reflecting part 12
has the second reflecting surface (12-3), adjusting .DELTA.h1 and
.DELTA.h2 allows the amount of light having biological information
(i.e., valid light) and light not having biological information
(i.e., invalid light: noise) incident on the light-receiving part
16 to be respectively adjusted, thereby making it possible to
further improve the S/N.
[0031] FIGS. 3(A) and 3(B) respectively show an example of an outer
appearance of the first reflecting part 12 and the light-emitting
part 14 of FIG. 1 in plan view. In the example shown in FIG. 3(A),
in plan view (when viewed from e.g. towards the detection site O
shown in FIG. 1), an outer circumference of the first reflecting
part 12 is circular, where the diameter of the circle is e.g. 200
.mu.m to 11,000 .mu.m. In the example shown in FIG. 3(A), the wall
part (12-2) of the first reflecting part 12 surround the
light-emitting part 14 (see FIGS. 1 and 2(A)). The outer
circumference of the first reflecting part 12 may also be a
quadrilateral (or specifically, a square) in plan view as shown
e.g. in FIG. 3(B). Also, in the examples shown in FIGS. 3(A) and
3(B), in plan view (when viewed from e.g. towards the detection
site O shown in FIG. 1), the outer circumference of the
light-emitting part 14 is a quadrilateral (or specifically, a
square), where the length of one side of the square is e.g. 100
.mu.m to 10,000 .mu.m. The outer circumference of the
light-emitting part 14 may also be circular.
[0032] The first reflecting part 12 is made of metal whose surface
is subjected to mirror surface finishing, and thereby has a
reflective structure (or specifically, a mirror reflection
structure). The first reflecting part 12 may also be formed from
e.g. a resin whose surface is subjected to mirror surface
finishing. Specifically, for example, a base metal forming a base
of the first reflecting part 12 is readied, and a surface of the
base metal is then e.g. subjected to plating. Alternatively, a mold
of the first reflecting part 12 (not shown) is filled with a
thermoplastic resin, molding is performed, and a metal film, for
example, is then deposited by vapor deposition on a surface of the
mold.
[0033] In the examples shown in FIGS. 3(A) and 3(B), in plan view
(when viewed from e.g. towards the detection site O shown in FIG.
1), a region of the first reflecting part 12 other than that
directly supporting the light-emitting part 14 (the inner wall
surface 12-2 and the top surface 12-3, and a part of the support
part 12-1) is exposed. The exposed region is shown as a mirror
surface part 12-4 in FIG. 2(A). Although in the example shown in
FIG. 2(A), a dotted line representing the mirror surface part 12-4
is shown within the first reflecting part 12, the mirror surface
part 12-4 is actually formed on a surface of the first reflecting
part 12.
[0034] In the examples shown in FIGS. 2(A), 2(B), and 2(C), the
mirror surface part 12-4 preferably has a high reflectivity. The
reflectivity of the mirror surface part 12-4 is e.g. 80% to 90% or
higher. It is possible for the mirror surface part 12-4 to be
formed only on the inclined surface of the inner wall surface 12-2.
In an instance in which the mirror surface part 12-4 is formed not
only on the inclined surface of the inner wall surface 12-2 but
also on the support part 12-1, the directivity of the
light-emitting part 14 increases further. In an instance in which
the mirror surface part 12-4 is formed on the top surface 12-3, the
first reflecting part 12 is capable of reflecting the reflected
light R1'', which has been reflected in the surface SA of the test
subject (i.e., the directly reflected light; invalid light),
towards the detection site O or the surroundings thereof, as shown
e.g. on FIG. 1, and the reflected light R1'' is deterred from
reaching the second reflecting part 18 and the light-receiving part
16. Since the directivity of the light-emitting part 14 increases
and the directly reflected light (or in a broader sense, noise)
decreases, the detection accuracy of the biological information
detector increases.
[0035] FIG. 4 shows another example of a configuration of the
biological information detector according to the present
embodiment. As shown in FIG. 4, the biological information detector
may further comprise a substrate 41 having a first surface (e.g. a
front surface) and a second surface that is opposite the first
surface (e.g. a reverse surface). Structures that are identical to
those in the example described above are affixed with the same
numerals, and a description of the structures will be omitted. In
the example shown in FIG. 4, the light-receiving part 16 is
positioned on the first surface, and the first reflecting part 12
is positioned on the second surface. When, in cross-section view,
W1 is a maximum value for the length of the first reflecting part
12 in a direction parallel to the first surface, and W2 is a
maximum value for the length of the light-receiving part 16 in the
same direction, an equation W1.ltoreq.W2 is satisfied.
[0036] The substrate 41 is formed of e.g. a transparent material
(e.g. polyimide) and allows transmission of the reflected light R1'
produced by the first light R1 emitted at the detection site O, and
other light. The maximum value W1 for the length of the first
reflecting part 12 is made equal to or less than the maximum value
W2 for the length of the light-receiving part 16, thereby making it
possible to increase the amount of light reaching the second
reflecting part 18. In other words, the maximum value W1 for the
length of the first reflecting part 12 can be set so that the first
reflecting part 12 does not block or reflect the reflected light
R1' reflected at the detection site O. The thickness of the
substrate 41 is e.g. 10 .mu.m to 1000 .mu.m. Wiring for the
light-emitting part 14 and wiring for the light-receiving part 16
may be formed on the substrate 41. The substrate 41 is e.g. a
printed circuit board; however, a printed circuit board is not
generally formed from a transparent material, as with the substrate
15 of Patent Citation 1. Specifically, the inventors purposefully
used a configuration in which the printed circuit board is formed
from a material that is transparent at least with respect to the
emission wavelength of the light-emitting part 14.
[0037] In the example shown in FIG. 4, the second light R2 emitted
at the detection site O via the first reflecting part 12, the
reflected light R2' reflected at the detection site O, and the
reflected light R1'' reflected at the surface SA of the test
subject (i.e., the directly reflected light) are omitted (refer to
FIG. 1). Those skilled in the art should be readily able to
understand the path of the second light R2 and the accurate path of
the first light R1.
[0038] As shown in FIG. 4, the biological information detector may
further contain a protecting part 49 for protecting the first
reflecting part 12 and the light-emitting part 14. The protecting
part 49 is formed from e.g. a transparent material (e.g. glass),
and allows transmission of the first light R1 emitted at the
detection site O, the reflected light R1' produced by the first
light R1 being reflected, and other light. The protecting part 49
also makes it possible to ensure that there is a gap between the
first reflecting part 12 and the detection site O (e.g. .DELTA.h2).
There also exists a gap between the first reflecting part 12 and
the protecting part 49 (e.g. .DELTA.h2'). The thickness of the
protecting part 49 is e.g. 1 .mu.m to 1000 .mu.m.
[0039] The substrate 41 is held between the second reflecting part
18 and the protecting part 49; the light-receiving part 16 is
placed on the substrate 41 towards the second reflecting part 18
(or specifically, on the first surface of the substrate 41); and
the light-emitting part 14 is placed on the substrate 41 towards
the protecting part 49 (or specifically, on the second surface of
the 41). Since the substrate 41 is held between the second
reflecting part 18 and the protecting part 49, even when the
light-emitting part 14 and the light-receiving part 16 are
positioned on the substrate 41, there is no need to separately
provide a mechanism for supporting the substrate 41 itself, and the
number of components is smaller. Also, since the substrate 41 is
formed from a material that is transparent with respect to the
emission frequency, the substrate 41 can be disposed on a light
path from the light-emitting part 14 to the light-receiving part
16, and there is no need to accommodate the substrate 41 at a
position away from the light path, such as within the second
reflecting part 18. A biological information detector that can be
readily assembled can thus be provided.
[0040] FIG. 5 shows an example of an outer appearance of the
light-receiving part 16 in FIG. 4. In the example shown in FIG. 5,
in plan view (e.g. when viewed from a side towards the second
reflecting part 18 in FIG. 4), an outer circumference of the
light-receiving part 16 is a quadrilateral (or specifically, a
square), and one side of the square is e.g. 100 .mu.m to 10,000
.mu.m. An outer circumference of the first reflecting part 12 is,
in plan view (e.g. when viewed from a side towards the second
reflecting part 18 in FIG. 4), circular. The outer circumference of
the first reflecting part 12 may instead be a quadrilateral (or
specifically, a square), as in the example shown in FIG. 3(B). The
outer circumference of the light-receiving part 16 may also be
circular.
[0041] In the example shown in FIG. 5, as shown by line segment
A-A', when W1 is a maximum value for the length of the first
reflecting part 12 and W2 is a maximum value for the length of the
light-receiving part 16, an equation W1.ltoreq.W2 is satisfied. A
cross-section view along the line segment A-A' in FIG. 5
corresponds to FIG. 4. A cross-section view along line segment B-B'
in FIG. 5 resembles FIG. 1, and the maximum value W1 of the length
of the first reflecting part 12 is larger than a minimum value of
the length of the light-receiving part 16. Although the maximum
value W1 of the length of the first reflecting part 12 may be set
so as to be equal to or smaller than the minimum value of the
length of the light-receiving part 16, the efficiency of the first
reflecting part 12 (or, in a broader sense, the efficiency of the
light-emitting part 14) would decrease. In the example shown in
FIG. 5, the maximum value W1 of the length of the first reflecting
part 12 is set to be equal or smaller than the maximum value W2 of
the length of the light-receiving part 16, and the maximum value W1
of the length of the first reflecting part 12 is set to be larger
than the minimum value of the length of the light-receiving part
16, so that the efficiency of the light-emitting part 14 can be
maintained without blocking or reflecting the reflected light
R1'.
[0042] FIG. 6 is a schematic diagram showing a setting position of
the second reflecting part 18 in FIG. 1 or 4. The reflecting
surface of the second reflecting part 18 may be formed as e.g. a
spherical surface (or in a broader sense, a dome surface), so that
the reflected light R1', produced by the first light R1 being
reflected at the detection site O, is reflected towards the
light-receiving part 16. As shown in FIG. 6, in cross-section view,
the reflecting surface of the second reflecting part 18 is an arc.
The radius of the arc is e.g. 1000 .mu.m to 15,000 .mu.m. A center
C of the arc that defines the spherical surface is located within
the test subject. In an instance in which the detection site O is
located within the test subject, the reflected light R1' reflected
at the surface SA of the test subject is an invalid light not
having biological information. The inventors identified that in an
instance in which the reflecting surface of the second reflecting
part 18 is formed by a spherical surface and the center C of the
arc that defines the spherical surface, the second reflecting part
18 minimizes reflected light reflected at the surface SA of the
test subject (or in a broader sense, noise). In FIG. 6, the
distance between the light-receiving surface of the light-receiving
part 16 and the center C of the arc that defines the spherical
surface is represented by .DELTA.h.
[0043] The reflecting surface of the second reflecting part 18 may
also be formed by a parabolic surface (or in a broader sense, a
dome surface) instead of the spherical surface. As shown in FIG. 6,
in cross-section view, the reflecting surface of the second
reflecting part 18 is an arc, but may be a parabolic line instead
of an arc. If the reflecting surface of the second reflecting part
18 is a parabolic surface, the focus of the parabolic line defining
the parabolic surface is shown in FIG. 6 by the letter F. The focus
F of the parabolic line defining the parabolic surface is located
towards the test subject relative to the light-receiving surface of
the light-receiving part 16. Light that travels perpendicular to
the surface SA of the test subject reflects at the reflecting
surface of the second reflecting part 18 (i.e., the parabolic
surface) and collects at the focus F of the parabolic line defining
the parabolic surface. Therefore, the focus F being located so as
to not coincide with the light-receiving surface of the
light-receiving part 16 results in a greater likelihood of light
having a path that is nearly perpendicular to the surface SA of the
test subject (e.g. the reflected light R1' produced by reflection
of the first light R1; valid light) collecting on the
light-receiving surface of the light-receiving part 16.
[0044] The second reflecting part 18 is formed from e.g. a resin,
whose surface (i.e., the reflecting surface facing the
light-receiving part 16) is subjected to mirror surface finishing,
and thereby has a reflective structure (or specifically, a mirror
reflection structure). In other words, the second reflecting part
18 is capable of causing mirror reflection of light without causing
diffuse reflection of light. In an instance in which the second
reflecting part 18 has a mirror reflection structure, the second
reflecting part 18 is also capable of not causing the reflected
light R1'' (i.e., the directly reflected light) to reflect towards
the light-receiving part 16, where the reflected light R1''
produced by reflection of the first light R1 has a reflection angle
that is different to that of the reflected light R1' produced by
reflection of the first light R1. In such an instance, the
detection accuracy of the biological information detector further
increases. As shown in FIG. 6, since the reflected light R1'
produced by reflection of the first light R1 originates from the
detection site O that is within the test subject, the reflection
angle of the reflected light R1' produced by reflection of the
first light R1 (i.e., a reflection angle relative to a straight
line perpendicular to the surface SA of the test subject) is
generally small. Meanwhile, since the reflected light R1'' produced
by reflection of the first light R1 originates from the surface SA
of the test subject, the reflection angle of the reflected light
R1'' produced by reflection of the first light R1 is generally
large.
[0045] In FIG. 16 of Patent Citation 1, there is disclosed a
reflecting part 131, and according to paragraphs [0046], [0059],
and [0077] in Patent Citation 1, the reflecting part 131 has a
diffuse reflection structure, and the reflectivity is increased to
increase the efficiency of the first reflecting part 12. However,
at the time of filing, it had not been recognized by those skilled
in the art that in the reflecting part 131 according to Patent
Citation 1, directly reflected light (or in a broader sense, noise)
is also reflected towards the first reflecting part 12. In other
words, the inventors identified that reducing a noise component
arising from the directly reflected light from a light reception
signal increases the efficiency of the light-receiving part.
Specifically, the inventors identified that the detection accuracy
of the biological information detector is further increased in an
instance in which the second reflecting part 18 has a mirror
reflection structure.
[0046] FIG. 7 is a diagram showing a relationship between the
setting position of the second reflecting part 18 and the amount of
light received at the light-receiving part 16 in FIG. 6. As shown
in FIG. 7, with increasing distance .DELTA.h between the
light-receiving surface of the light-receiving part 16 and the
center C of the arc defining the spherical surface, the amount of
directly reflected light reflected at the surface SA of the test
subject (or, in a broader sense, noise corresponding to the
reflected light R1'', for example) decreases, while light reflected
at the detection site O (or, in a broader sense, biological
information corresponding to reflected light R1', for example)
increases and then decreases. The position of the .DELTA.h can
accordingly be optimized. In an instance in which the reflecting
surface of the second reflecting part 18 is a parabolic surface,
the distance between the light-receiving part of the
light-receiving part 16 and the focus F of the parabolic line
defining the parabolic surface can also be optimized.
2. Biological Information Measuring Device
[0047] FIGS. 8(A) and 8(B) are examples of outer appearances of a
biological information measuring device containing the biological
information detector such as that shown in FIG. 1. As shown in FIG.
8(A), the biological information detector shown in FIG. 1, for
example, may further contain a wristband 80 capable of attaching
the biological information detector to an arm (or specifically, a
wrist) of the test subject (i.e., the user). In the example shown
in FIG. 8(A), the biological information is the pulse rate
indicated by e.g. "72." The biological information detector is
installed in a watch showing the time (e.g. "8:15 am"). As shown in
FIG. 8(B), an opening part is provided to a back cover of the
watch, and the protecting part 49 shown in FIG. 4, for example, is
exposed in the opening part. In the example shown in FIG. 8(B), the
second reflecting part 18 and the light-receiving part 16 are
installed in a watch. In the example shown in FIG. 8(B), the first
reflecting part 12, the light-emitting part 14, the wristband 80,
and other components are omitted.
[0048] FIG. 9 is an example of a configuration of the biological
information measuring device. The biological information measuring
device includes the biological information detector as shown e.g.
in FIG. 1, and a biological information measuring part for
measuring biological information from a light reception signal
generated at the light-receiving part 16 of the biological
information detector. As shown in FIG. 9, the biological
information detector may have a light-emitting part 14 and a
control circuit 91 for controlling the light-emitting part 14. The
biological information detector may further have an amplification
circuit 92 for amplifying the light reception signal from the
light-receiving part 16. The biological information measuring part
may have an A/D conversion circuit 93 for performing A/D conversion
of the light reception signal from the light-receiving part 16, and
a pulse rate computation circuit 94 for computationally obtaining
the pulse rate. The biological information measuring part may
further have a display part 95 for displaying the pulse rate.
[0049] The biological information detector may have an acceleration
detecting part 96, and the biological information measuring part
may further have an A/D conversion circuit 97 for performing A/D
conversion of a light reception signal from the acceleration
detecting part 96 and a digital signal processing circuit 98 for
processing a digital signal. The configuration of the biological
information measuring device is not limited to that shown in FIG.
9. The pulse rate computation circuit 94 in FIG. 9 may be e.g. an
MPU (i.e., a micro processing unit) of an electronic device
installed with the biological information detector.
[0050] The control circuit 91 in FIG. 9 drives the light-emitting
part 14. The control circuit 91 is e.g. a constant current circuit,
delivers a predetermined voltage (e.g. 6 V) to the light-emitting
part 14 via a protective resistance, and maintains a current
flowing to the light-emitting part 14 at a predetermined value
(e.g. 2 mA). The control circuit 91 is capable of driving the
light-emitting part 14 in an intermittent manner (e.g. at 128 Hz)
in order to reduce consumption current. The control circuit 91 is
formed on e.g. a motherboard, and wiring between the control
circuit 91 and the light-emitting part 14 is formed e.g. on the
substrate 41 shown in FIG. 4.
[0051] The amplification circuit 92 shown in FIG. 9 is capable of
removing a DC component from the light reception signal (i.e., an
electrical current) generated in the light-receiving part 16,
extracting only an AC component, amplifying the AC component, and
generating an AC signal. The amplification circuit 92 removes the
DC component at or below a predetermined wavelength using e.g. a
high-pass filter, and buffers the AC component using e.g. an
operational amplifier. The light reception signal contains a
pulsating component and a body movement component. The
amplification circuit 92 and the control circuit 91 are capable of
feeding a power supply voltage for operating the light-receiving
part 16 at e.g. reverse bias to the light-receiving part 16. In an
instance in which the light-emitting part 14 is intermittently
driven, the power supply to the light-receiving part 16 is also
intermittently fed, and the AC component is also intermittently
amplified. The amplification circuit 92 is formed on e.g. the
mother board, and wiring between the amplification circuit 92 and
the light-receiving part 16 is formed on e.g. the substrate 41
shown in FIG. 4. The amplification circuit 92 may also have an
amplifier for amplifying the light reception signal at a stage
prior to the high-pass filter. In an instance in which the
amplification circuit 92 has an amplifier, the amplifier is formed
e.g. on the substrate 41 shown in FIG. 4.
[0052] The A/D conversion circuit 93 shown in FIG. 9 converts an AC
signal generated in the amplification circuit 92 into a digital
signal (i.e., a first digital signal). The acceleration detecting
part 96 shown in FIG. 9 calculates e.g. gravitational acceleration
in three axes (i.e., x-axis, y-axis, and z-axis) and generates an
acceleration signal. Movement of the body (i.e., the arm), and
therefore the movement of the biological information measuring
device, is reflected in the acceleration signal. The A/D conversion
circuit 97 shown in FIG. 9 converts the acceleration signal
generated in the acceleration detecting part 96 into a digital
signal (i.e., a second digital signal).
[0053] The digital signal processing circuit 98 shown in FIG. 9
uses the second digital signal to remove or reduce the body
movement component in the first digital signal. The digital signal
processing circuit 98 may be formed by e.g. an FIR filter or
another adaptive filter. The digital signal processing circuit 98
inputs the first digital signal and the second digital signal into
the adaptive filter and generates a filter output signal in which
noise has been removed or reduced.
[0054] The pulse rate computation circuit 94 shown in FIG. 9 uses
e.g. fast Fourier transform (or in a broader sense, discrete
Fourier transform) to perform a frequency analysis on the filter
output signal. The pulse rate computation circuit 94 identifies a
frequency that represents a pulsating component based on a result
of the frequency analysis, and computationally obtains a pulse
rate.
[0055] A first aspect of the illustrated embodiment relates to a
biological information detector, characterized in comprising: a
light-emitting part subjected to emit a first light directed at a
detection site of a test subject and a second light directed in a
direction other than a direction of the test subject; a first
reflecting part subjected to reflect the second light and directing
the second light towards the detection site; a light-receiving part
subjected to receive light having biological information, the light
produced by the first light and the second light being reflected at
the detection site; and a second reflecting part subjected to
reflect the light having biological information from the detection
site and directing the light having biological information towards
the light-receiving part.
[0056] According to the first aspect of the illustrated embodiment,
the second light, which does not directly arrive at the detection
site of the test subject (e.g. a user), also reaches the detection
site via the first reflecting part. Therefore, the amount of light
reaching the detected part increases, and the detection accuracy
(i.e., signal-to-noise ratio) of the biological information
detector improves.
[0057] According to a second aspect of the illustrated embodiment,
the light-emitting part may have: a first light-emitting surface
for emitting the first light, the first light-emitting surface
facing the detection site; and a second light-emitting surface for
emitting the second light, the second light-emitting surface being
a side surface of the first light-emitting surface; the first
reflecting part may have a wall part surrounding the second
light-emitting surface; and the wall part may have a first
reflecting surface for reflecting the second light towards the
detection site.
[0058] The wall part (i.e., the first reflecting part) surrounding
the second light-emitting surface of the light-emitting part having
the first reflecting surface thus increases the amount of light
reaching the detection site, and the accuracy of the biological
information detector further increases.
[0059] According to a third aspect of the illustrated embodiment,
the wall part may further have a second reflecting surface for
reflecting light that has been reflected at a surface of the test
subject and does not contain biological information, thereby
suppressing the light not having biological information from being
incident on the light-receiving part.
[0060] The second reflecting surface of the first reflecting part
is thus capable of minimizing incidence of light not having
biological information (i.e., invalid light) onto the
light-receiving part and improve the S/N (i.e., signal-to-noise
ratio).
[0061] According to a fourth aspect of the illustrated embodiment,
the first reflecting part may project further towards the detection
site than the light-receiving part.
[0062] Specifically, the shortest distance between the first
reflecting part and the surface of the test subject may be smaller
than the shortest distance between the light-emitting part and the
surface of the test subject. The first reflecting part may thus
project towards the detection site by e.g. a predetermined height
.DELTA.h1 in relation to a surface of the light-emitting part that
determines the shortest distance relative to the surface of the
test subject (e.g. the first light-emitting surface). Specifically,
a spacing between the first reflecting part and the surface of the
test subject (e.g. .DELTA.h2=.DELTA.h0-.DELTA.h1) may be smaller
than a spacing that represents the shortest distance between the
light-receiving part and the surface of the test subject (e.g.
.DELTA.h0=.DELTA.h1+.DELTA.h2). Therefore, in the first reflecting
part, the presence of e.g. a projection .DELTA.h1 from the
light-emitting part makes it possible to increase the area of the
first reflecting surface and increase the amount of light reaching
the detection site. Also, with regards to the light reflected at
the detection site, the presence of e.g. .DELTA.h2 makes it
possible to obtain a light path for the light to reach the second
reflecting part from the detection site. Also, in an instance in
which the first reflecting part has the second reflecting surface,
adjusting .DELTA.h1 and .DELTA.h2 allows the amount of light having
biological information (i.e., valid light) and light not having
biological information (i.e., invalid light: noise) incident on the
light-receiving part to be respectively adjusted, thereby making it
possible to further improve the S/N.
[0063] According to a fifth aspect of the illustrated embodiment,
the biological information detector may further comprise a
substrate having a first surface, and a second surface facing the
first surface; wherein the light-receiving part may be positioned
on the first surface; the first reflecting part may be positioned
on the second surface; and an equation W1.ltoreq.W2 may be
satisfied, when, in a cross-sectional view, W1 is a maximum value
for the length of the first reflecting part in a direction parallel
to the first surface, and W2 is a maximum value for the length of
the light-receiving part in the direction parallel to the first
surface.
[0064] Having the maximum value W1 for the length of the first
reflecting part be equal to or smaller than the maximum value W2
for the length of the light-receiving part thus makes it possible
to increase the valid amount of light reaching the second
reflecting part. Specifically, the maximum value W1 for the length
of the first reflecting part may be set so that the first
reflecting part does not block or reflect light reflected at the
detection site (i.e., reflected light having biological
information).
[0065] According to a sixth aspect of the illustrated embodiment, a
reflecting surface of the second reflecting part may be a spherical
surface or a parabolic surface, wherein a center of an arc defining
the spherical surface may be within the test subject, or a focus of
a parabolic line defining the parabolic surface may be towards the
test subject relative to a light-receiving surface of the
light-receiving part.
[0066] In an instance in which the detection site is within the
test subject, light reflected at the surface of the test subject
does not contain biological information. The inventors identified
that the second reflecting part minimizes light reflected at the
surface of the test subject (or in a broader sense, noise) in an
instance in which the center of the arc defining the spherical
surface is within the test subject. Also, in an instance in which
the reflecting surface of the second reflecting part is a parabolic
surface, and the focus of the parabolic line defining the parabolic
surface is towards the test subject relative to the light-receiving
surface of the light-receiving part, there is a greater likelihood
of light having a path that is nearly perpendicular to the surface
of the test subject (e.g. the reflected first light; valid light)
collecting on the light-receiving surface of the light-receiving
part.
[0067] According to a seventh aspect of the illustrated embodiment,
the biological information detector may further contain a wristband
capable of attaching the biological information detector to an arm
of the test subject.
[0068] The detection site can thus be set on the arm of the test
subject (i.e., the user). In other words, the biological
information detector whose detection accuracy has been improved can
be applied in an environment in which there is a significant level
of noise arising from external light.
[0069] An eighth aspect of the illustrated embodiment relates to a
biological information measuring device, characterized in
comprising: the biological information detector described above;
and a biological information measuring part for measuring
biological information from a light reception signal generated at
the light-receiving part.
[0070] According to the eighth aspect of the illustrated
embodiment, the biological information detector whose detection
accuracy has been improved can be used to increase the measurement
accuracy of the biological information measuring device.
[0071] Although a detailed description was made concerning the
present embodiment as stated above, persons skilled in the art
should be able to easily understand that various modifications are
possible without substantially departing from the scope and effects
of the present invention. Accordingly, all of such examples of
modifications are to be included in the scope of the present
invention. For example, terms stated at least once together with
different terms having broader sense or identical sense in the
specification or drawings may be replaced with those different
terms in any and all locations of the specification or
drawings.
* * * * *